The role of rays in the ecosystem

The role of rays in the
ecosystem
By Simon Pierce
A tropical whipray (Himantura sp.) (© Shane Litherland)
THE ROLE OF RAYS IN THE ECOSYSTEM
By Simon Pierce
School of Biomedical Sciences, The University of Queensland,
St. Lucia, Queensland 4072 Australia
Introduction to rays and skates
The rays are the most diverse of the cartilaginous fishes,
encompassing around 600 species worldwide. These range
from the gigantic manta rays, with a ‘wingspan’ of over six
metres, right down to skates the size of a person’s hand.
Though they are diverse in body form, a common characteristic
of rays is their flattened bodies. Most stingrays have rounded,
flat, expanded pectoral fins that form a body ‘disc’ so they
are ideally adapted to burying themselves in the substrate,
where they are both camouflaged and streamlined. The disc
is amazingly flexible near its margin, which is important for
swimming, burying, and feeding. The pectoral fins of pelagic
ray groups, such as eagle rays and mantas, are more wing-like
with strong lateral muscles for prolonged swimming, allowing
them to ‘fly’ through the water (figure 1).
Figure 1. A typical encounter with a large ray, swimming close to the
sea floor (© Andrea Marshall).
Geographically, rays are distributed from thousands of
kilometres inland in South America right up to the Arctic
Circle, and from the intertidal zone down to abyssal depths.
Most rays live exclusively in the sea, and the majority live over
the continental shelves, from the intertidal zone to depths of
200 metres, while skates take over from the stingrays in deeper
waters. Their wide distribution and diversity means that rays
have an important role in almost all marine ecosystems, with
each species having its own distinctive niche.
The ocean is a three-dimensional environment, with underwater
habitats structured both vertically and horizontally. Almost
all rays feed on prey living close to, on, or just underneath
the bottom, acting somewhat like the vacuum cleaners of the
ocean. The bottom is generally the most productive part of the
ocean as dead things tend to end up there. Hence, the things
that directly or indirectly feed on them accumulate on the
bottom as well. Rays feed mainly on invertebrates and small
vertebrates, with prey ranging from large fish down to tiny
crustaceans. All known rays are carnivorous, and as a group
they are high in the food web.
Rays can be quite selective feeders, and the various shapes of
their mouth and teeth can be a good indication of their food
preferences. Eagle and cownose rays have a series of flattened
tooth plates for crushing hard-shelled molluscs. Rays that often
feed on fish, such as torpedo rays, have an arched lower jaw
studded with small spiny teeth which can be thrust forward to
suck up small fish. The huge mouth of the plankton-feeding
manta ray is at the front of the snout, while the teeth, which are
not important in feeding, are minute and covered in skin in the
lower jaw and totally absent in the upper jaw (figure 2). Skates
and most stingrays have compact rows of strong, pointed teeth
in both jaws for holding and crushing their prey (figure 3).
Figure 2. Manta rays can grow to have a wingspan many metres
across, but feed on small organisms filtered from the water. They are
often accompanied by remoras or suckerfish that ‘hitch a ride’ to the
rays using a specialised suction mechanism on the top of their head
(© Andrea Marshall).
Sensory biology
As the majority of rays are bottom dwellers, their mouth is
located on the under-surface of the disc. This means that
they often cannot see what they are eating. To find their
prey without vision, rays have developed a host of other
sophisticated sensory systems including good vision (colour
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Figure 3. This bluespot fantail ray (Taeniura lymma) is commonly
encountered on and around coral reefs. Coral sand, thrown up during
‘pit-digging’ can be seen on the back of the ray. The protruded jaws
are visible under the animal as the ray feeds (© Andrea Marshall).
vision in at least some species); an ability to ‘touch’ things
from a distance by using their lateral line systems to detect
minute water currents; an acute sense of hearing; and the ability
to detect one drop of fish extract in 10 billion drops of water.
Rays also possess another sense that is quite alien to humans:
electrosensory organs, known as the ampullae of Lorenzini,
which are clustered around the head and mouth of rays. The
weak bioelectric signals, created by muscle contraction and
the nervous system in potential prey, can be detected by rays,
which perceive these signals as an ‘aura’ around the animal. In
combination, this sensory capability ensures rays are efficient
in detecting subsurface prey.
Shallow water ecosystems
Rays are apex predators in the inshore environment. Tropical
estuaries, tidal flats, and mangrove swamps are some of the
most productive ecosystems on Earth. Rays may partition
themselves within these environments by their daily or seasonal
patterns of activity, foraging behaviour or diet, allowing a high
abundance and diversity of ray species to share the riches of
these habitats.
Stingrays hunt by gliding slowly over soft seabed (figure 4),
searching for the water currents created by: filter-feeding
bivalves; the electrical signals given off by burrowing crabs;
small shrimp darting off, or whatever their particular food
preference may be. On detection of subsurface prey, a ray
will settle over the spot, pump water through the modified
gill opening (the spiracle) behind its eye, and jet this water
out through its gills on the under-surface of its body to
hydraulically mine the sediment and uncover the prey. This
leaves a ‘feeding pit’ at the site. These pits are most visible
in the intertidal zone, where there will characteristically be a
depression with a pile of sediment immediately down-current.
Figure 4. Many rays such as this species of Himantura can often
be found feeding in very shallow water, usually over sand or mud
substrates (© Shane Litherland).
This disturbance of bottom sediments can have a major effect
on the inshore ecosystem. For example, within intertidal
sandflats in northern New Zealand, a particular patch of
sediment may be excavated once every 70 days by eagle rays;
while in the subtidal environment off La Jolla, California,
5.4 percent of transect areas was disturbed by rays every day
during warm months (when ray abundance is high) and 25–100
percent of the bottom area may be in some stage of recovery
and recolonisation from ray feeding disturbances. Initially, the
formation of feeding pits clears all the infaunal invertebrates,
but rapid accumulation of organic material in the bottom of the
pit results in elevated food availability, which attracts certain
invertebrate species. These species recolonise pits at variable
rates, creating a mosaic of infaunal communities throughout
the benthic habitat in different stages of recolonisation. Ray
impacts over soft bottoms may best be understood as largescale habitat modification. Since rays are abundant throughout
tropical and temperate areas, they are probably important in
structuring benthic communities in many locations.
Pelagic zone ecosystems
The pelagic zone, from above the seabed to the surface,
is the habitat of rays that feed off the bottom. Only a few
species have made this their home, but these include the
largest of the rays. The gigantic plankton-feeding manta and
devil rays, both of which feed mainly near the surface over
the continental shelf, occur throughout the tropical seas of
the world from inshore right out into the open sea. Manta
rays funnel microscopic plankton into their mouth using its
extended cephalic lobes, which remain folded spirally when
not in use. Then, with a sophisticated filtering system, it sieves
the plankton from the same water that it uses to breathe. Only
one stingray has found itself a niche in the pelagic zone, but
this species, the pelagic stingray, is found nearly worldwide in
tropical and subtropical seas, with its distribution extending to
temperate latitudes.
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Figure 5. This bluespot maskray (Dasyatis kuhlii) seen on the sorting
tray of a trawler was caught as bycatch in a prawn fishery
(© Peter Kyne).
about their biology and lifestyle. It is likely that there are
many more species in the deep oceans of the world that remain
unknown to science at present.
Deep water ecosystems
Threatening processes
Almost half of the world’s rays occur only in the cool, deep
waters of the outer continental shelves and slopes. Skates
are the main group of deep-water rays. Most of the 280 or so
species are found throughout the world in the deeper waters
along continental margins, on soft bottoms down to depths of
3000 metres or more. Most species have rather restricted ranges
geographically, and the skates of nearby regions are often quite
distinct, indicating that they probably do not range widely.
Rays are high-level predators within the ecosystem, and as
such have few predators. Their low natural rate of mortality
has allowed them to adopt a life history strategy focussed
on producing a few, large young. Compared to most bony
fish, rays are long-lived, slow-growing, and have delayed
maturation. Unfortunately, these same characteristics make rays
highly vulnerable to human-induced pressures, such as fishing,
habitat degradation and pollution.
Much of the deep-sea floor is muddy ooze. Skates feed on
bottom-dwelling animals, such as soft-shelled molluscs,
sand worms, crustaceans, and small fishes. Some deep-water
skates use their long, firm snouts (covered in sensory pores)
to ‘grub around’ in the soft upper layers. The equally long,
but softer and more flexible snout of the sixgill stingrays
(Hexatrygonidae) appears to be used like a finger to probe
more deeply into the sediments for food, while other skates
target the fishes that forage in these areas. Although skates
are probably important in the ecology of the deep sea, many
species are known from very few specimens and little is known
Rays are a common catch within many fisheries, both inshore
and offshore. Although rays are targeted in fisheries elsewhere
in the world, in Australia they are largely caught accidentally,
as a bycatch of commercial and recreational fisheries targeting
other species (figure 5). Most fishing pressure occurs in waters
over the continental shelves, putting the species living in this
area at risk. Deep-water rays are even more susceptible to
fishing pressures than coastal and pelagic species, as the low
productivity of the deep ocean floor means that many of the
species found here grow extremely slowly and have a low
reproductive rate. As a consequence, many of these species are
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naturally rare. Many species are found in only a small area,
while others may exist only in specific habitats over a wider
area. Fisheries in the deep sea are still being commercially
developed, and rays will increasingly be caught as bycatch in
these areas. Unfortunately, the low productivity of these rays
means that species can be heavily reduced, even to extinction,
before the targeted bony fish species shows a significant
decline in catch.
Habitat modification and pollution are also major issues for
some inshore species. Estuarine and coastal areas are suffering
increasing alteration through development, restriction of river
flows, land reclamation and other pressures. The young of
many inshore species spend their first few months or years in
high productivity ‘nursery’ areas. Often these are located in
estuaries or shallow mangrove-fringed ecosystems where there
is plenty of food and protection from larger predators. The
removal or degradation of these areas can result in a permanent
reduction in the local ray population.
Acknowledgements
The following organisations/individuals are acknowledged for their
contributions: Funding: Natural Heritage Trust and the Fisheries
Resources Research Fund (Australian Government Department
of Agriculture, Fisheries and Forestry). Coordination of project:
Marine Industries Environment Branch and the Bureau of Rural
Sciences (Australian Government Department of Agriculture,
Fisheries and Forestry). Artwork: Brett Cullen and Trish Hart.
Reviewers: Carolyn Stewardson and Albert Caton.
© Simon Pierce ([email protected]).
This information sheet may be copied for educational purposes.
For any other purpose please contact the author.
Rays are present in most marine ecosystems worldwide, and
have a vital role in maintaining the health and function of these
ecosystems. Their ecological niche has been little-studied
when compared to sharks, but their diversity, abundance and
worldwide distribution testifies to their success. The challenge
for marine science now is to ensure these rays are protected, so
they do not quietly disappear before we can fully understand
just how important they are.
Further information
For terms in this text that may be unfamiliar to you please visit
fishbase:
http://www.fishbase.org/search.cfm
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